Multi-zone closed loop daylight harvesting having at least one light sensor

ABSTRACT

A multi-zone daylight harvesting method and apparatus having a closed loop system utilizing a single light sensor is disclosed herein. This light control system includes an ambient light sensor connected to a detection circuit for detecting the amount of ambient light within a given zone and converting the light signal to an digital one. A control device couples to receive a predetermined rate of change for each respective zone from a storage unit along with the converted digital signal. The control device connects each zone of a plurality of electrical loads to control the power supplied to the electrical load at the predetermined corresponding rate of change and responsive to the amount of ambient light detected.

This application claims the benefit of the filing date of a provisionalapplication having Ser. No. 60/677,919 which was filed on May 5, 2005.

FIELD OF THE INVENTION

The present invention relates to light control systems, and, moreparticularly, to a multi-zone closed loop daylight harvesting having atleast one light sensor.

BACKGROUND OF THE INVENTION

Daylight harvesting is an available lighting strategy designed to reduceexcessive internal light levels during peak consumption hours, whereinexternal light sources, such as daylight, substitute for interiorelectrical lighting. For example, in an office setting, each work areamust at all times be provided with a minimum level of light which isdetermined based upon the tasks performed in the area or zone. Lighting,however, is generally installed by size and number sufficient to providethe minimum light level under the assumption that no other light sourcesare available in the interior space. Yet, during varying times of theday, other light sources may illuminate the interior space such that thelevel of light present is excessive. Thereby, the use of interiorlighting at the same level of intensity becomes a waste of energy.

Specifically, during the day, sunlight may enter through windows andskylights. When these external light sources are present, the presetbrightness of interior lighting is not necessary since these externallight sources provide some or all of the minimum light level required.Daylight harvesting eliminates the excessive level of intensity ofinterior lighting, conserving as much as 84% of the energy required tolight a facility at the minimum light level. As such, during midday,excess electrical lighting is minimized and bright sunlight is utilizedto provide up to 100% of illumination during midday, when energy costsare highest.

Daylight harvesting also provides a constant level of light on worksurfaces to avoid moments when the external light sources provide anexcessive amount of light, resulting in periods of glare. In thealternative, when light levels are low (i.e. when clouds roll in ornighttime falls), daylight harvesting maintains this constant level oflight by continuously increasing and decreasing the power applied to theinternal lighting. This practice enables the worker to resolve imageswith ease. As a result, eyestrain is avoided; and health andproductivity are promoted.

Conventional technology for implementing daylight harvesting techniquesincorporates the use of digital photo-sensors to detect light levels anddimmers to automatically adjust the output level of electric lightingfor promoting balance. Dimming control circuits, as implemented withrespect to daylight harvesting, gradually increase or decrease interiorlighting in response to photocell measurement of ambient light levels.

There are two kinds of light sensors are available. The “open-loop”sensor is positioned within a lighting system such that the sensormonitors the amount of light outside of a nearby window or skylight toread only the amount of light coming into the interior space fromoutside. The open loop sensor may be located within the interior spaceor outside of the interior space. The other kind of light sensor iscalled a “closed-loop” sensor. It generally is positioned on theceiling, facing downward towards a horizontal work-surface. This sensorreads the light reflected from the horizontal work-surface. As thelights dim or brighten in response to a signal generated by the sensor,the system is adjusted to maintain a desired lighting level.

For interior spaces having one zone of lighting, the aforementionedclosed-loop system is adequate. Within a closed loop system, one sensor,such as a photocell, couples to a dimmable control unit to control amultiple number of attached electrical loads, such as internal lightsources, within one zone. In this zone, all internal light sources aredimmed at the same pre-determined rate of change in response to anincrease or decrease in ambient light.

Adjusting all the internal light sources at the same rate is acceptablegiven the assumption that the external light sources affect every areaof the internal space in the same way at all times of the day. However,for interior spaces that have, for example, windows along one side ofthe wall, the areas closest to the windows receive a higher amount oflight than areas further from the windows. In such cases, a daylightharvesting scheme will require more than one zone, each having a numberof internal light sources, wherein the rate for dimming the internallight sources within each zone differs. There, however, is no knownclosed loop system that is able to control lighting sources in multiplezones.

Open loop systems, however, may be used in the implementation ofdaylight harvesting for an interior space having multiple zones. Openloop systems include a light system for a specific interior space, alight control circuit or sensor and an external source of light. Asmentioned above, the light control circuit is placed in a locationinside or outside of the specific interior space. The light controlcircuit measures the external source of light. This measurement is fedback into the system to control the interior light sources, whereby, anoutside source alone, i.e., the sun, controls the system output. Thesun, in effect, acts as a potentiometer controlling the lighting controlsystem. This type of system, however, suffers from less accurate controlthan closed loop systems because of seasonal and weather changes.

Thus, a need exists for a multi-zone daylight harvesting method andapparatus having a closed loop system that uses a single photocell orsensor to control a plurality of light sources in a plurality of zones.

The present invention is directed to overcoming, or at least reducingthe effects of one or more of the problems set forth above.

SUMMARY OF THE INVENTION

To address the above-discussed deficiencies of multi-zone daylightharvesting methods and apparatus, the present invention teaches amulti-zone daylight harvesting method and apparatus having a closed loopsystem utilizing a single photocell.

The design of the present invention permits a single sensing and controlcircuit to be connected directly to a plurality of internal lightsources to control these sources of light. The use of a single sensingand control circuit as described herein is particularly desirable sincethis method reduces cost and enhances reliability. In addition, a singlesensing and control circuit will provide more uniform control of lightsin a given area such as in a single room.

A light control system in accordance with the present invention includesan ambient light sensor connected to a detection circuit for detectingthe amount of ambient light within a given zone. A control deviceconnects between the detection circuit and multiple zones of electricalloads to control the power supplied to the electrical load based on theamount of ambient light detected. Each one of the zones includes adefined rate of change for adjusting the brightness of the electricalloads associated with each respective zone.

Advantages of this design include but are not limited to a multi-zonedaylight harvesting method and apparatus having a closed loop systemthat uses a single photocell or sensor to control a plurality of lightsources in a plurality of zones that employs a high performance, simple,and cost effective design.

These and other features and advantages of the present invention will beunderstood upon consideration of the following detailed description ofthe invention and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention and theadvantages thereof, reference is now made to the following descriptiontaken in conjunction with the accompanying drawings in which likereference numbers indicate like features and wherein:

FIG. 1A show a graph of the zone voltage as a function of the increasingexternal light in accordance with the present invention;

FIG. 1B displays an implementation of a three zone network of internallighting wherein one photocell detects the ambient light for all threezones in accordance with the present invention; and

FIG. 2 displays the multi-zone light control system in accordance withthe present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The present invention will now be described more fully hereinafter withreference to the accompanying drawings, in which embodiments of theinvention are shown. This invention may, however, be embodied in manydifferent forms and should not be construed as limited to theembodiments set forth herein. Rather, these embodiments are provided sothat this disclosure will be thorough and complete and will fully conveythe scope of the invention to those skilled in the art.

This invention describes an apparatus and method for allowing a daylightharvesting controller, within a closed loop system, to control more thanone zone with a single photocell. FIG. 1A displays a graph of the zonevoltage as a function of the increasing external light in accordancewith the present invention. FIG. 1B displays the corresponding layout ofa three zone network of internal lighting wherein one photocell detectsthe ambient light for all three zones. As shown in FIG. 1B, zone 1represents the plurality of light sources closest to the windows thatreceives the most light. When the external lighting increases at thewindow, the light sources of zone 1 must decrease rapidly as oppose tothe rate of decrease of intensity in the light sources of zone 2 andzone 3. Accordingly, the defined rate of change for zone 1 is higherthan that of zone 2 and zone 3. In the same relation, the light sourcesin zone 2 are closer to the external light source at the window than thelight sources in zone 3. Therefore, the defined rate of change for zone2 is higher than that of zone 3. In particular, as shown in FIG. 1B, thelight sensor or photocell may be located at any position within theinterior space of the room.

FIG. 2 displays the multi-zone light control system 200 in accordancewith the present invention. The system includes a light sensor 205, adetection circuit 210, a storage unit 215, a control device 220, and oneor more electrical loads 225. When light sensor 205 is exposed to light,it produces a small current or signal. The strength of the signal isproportional to the amount of light or illumination level sensed.Detection circuit 210 is connected to sensor 205 to receive the signalgenerated by light sensor 205 and converts the light energy into anelectrical signal. In addition, detection circuit 210 may amplify thesignal to a workable level to control the indirectly connectedelectrical loads 225 through control device 220. The electrical loads225 may be an electrical light source or a plurality of electrical lightsources Z_(i) (where i=1, 2, 3 . . . ). Storage unit 215 is connected tocontrol device 220 for storage of each respective rate of changevariable X_(n) (where n=1, 2, 3, . . . ) corresponding to each zone. Forexample, in a three zone daylight harvesting control system, storageunit 215 couples to receive rates of change, X₁, X₂, and X₃, whichrepresent the first, second, and third rate of change for a first zoneZ₁, a second zone Z₂, and a third zone Z₃, respectively. The storageunit 215 may be implemented in software using memory or in hardwareusing an electromechanical device such as a potentiometer. Controldevice 220 is coupled to storage unit 215 and receives these storedrates of change, X₁, X₂, and X₃, from storage unit 215. Control device220 adjusts the power supplied to the electrical load 225 in eachrespective zone, Z₁, Z₂, and Z₃, responsive to the detected ambientlight measurement from light sensor 205. The respective rates, X₁, X₂,and X₃, are used to control the various zones, Z₁, Z₂, and Z₃, throughrespective connections between each zone, Z₁, Z₂, and Z₃, and thecontrol device 220. A microprocessor may be used to implement thecontrol device.

Thus, the light control system in accordance with the present inventionprovides adjustments for each zone Z_(i) wherein a rate of change X_(n)for which the zone is determined. This rate of change X_(n) correspondsto the rate at which each internal light source must change itsillumination in maintaining the proper balance for daylight harvestingin each zone Z_(i). For example, in a three zone system as shown in FIG.2, the installer may want the zone closest to windows to change thefastest, the middle zone to change at half the rate and the far zone todim at a quarter of the rate.

The design of the present invention therefore permits a single sensingand control circuit to be connected directly to a plurality of internallight sources to control these sources of light. The use of a singlesensing and control circuit as described herein is particularlydesirable since this method reduces cost and enhances reliability. Inaddition, a single sensing and control circuit will provide more uniformcontrol of lights in a given area such as in a single room. Because ofambient light variation within areas, and because of variations incalibration and response between multiple sensing and control circuits,internal light sources in the same area that are controlled by differentsensing and control circuits may exhibit variation in light output. Thiscontinual variation may be annoying to persons working in the area.Thus, it is preferable to use a single sensing and control circuit tocontrol all the lamps in a lighting zone Z_(i).

Those of skill in the art will recognize that the physical location ofthe elements illustrated in FIG. 1 b can be moved or relocated whileretaining the function described above. For example, the photocell maybe positioned at any point within the interior space of the room tosense ambient light for the daylight harvesting control system inaccordance with the present invention.

It is understood that these rates may change given the type of weatherconditions that are present. For example, on a cloudy day verses a clearday, the rate of change should differ. The rates of change, however, mayremain consistent across multiple zones since each zone is affected bythe change in weather conditions.

The reader's attention is directed to all papers and documents which arefiled concurrently with this specification and which are open to publicinspection with this specification, and the contents of all such papersand documents are incorporated herein by reference.

All the features disclosed in this specification (including anyaccompanying claims, abstract and drawings) may be replaced byalternative features serving the same, equivalent or similar purpose,unless expressly stated otherwise. Thus, unless expressly statedotherwise, each feature disclosed is one example only of a genericseries of equivalent or similar features.

The terms and expressions which have been employed in the foregoingspecification are used therein as terms of description and not oflimitation, and there is no intention in the use of such terms andexpressions of excluding equivalents of the features shown and describedor portions thereof, it being recognized that the scope of the inventionis defined and limited only by the claims which follow.

1. A light control system for controlling the brightness of a pluralityof electrical loads, comprising: a control device capable of receiving alight detection signal and at least one rate of change corresponding toat least one zone having a plurality of electrical loads to controlpower provided to the at least one zone in proportion to each respectiverate of change.
 2. A light control system for controlling the brightnessof a plurality of electrical loads, comprising: an ambient light sensorthat outputs a first signal in response to being exposed to a radiationsource for sensing the ambient light level; a detection circuit coupledto the light sensor to generate a second signal from the first signal; acontrol device coupled to receive the second signal from the detectioncircuit to control the plurality of electrical loads; and at least onezone of the plurality of electrical loads coupled to the control device,the at least one zone of the plurality of electrical loads, each havinga predetermined rate of change for adjusting the brightness of theplurality of the electrical loads responsive to the ambient lightdetected.
 3. A light control system as recited in claim 2, wherein theat least one zone includes a first zone, a second zone and a third zone,wherein the first zone having a first predetermine rate of change, thesecond zone having a second predetermined rate of change, and a thirdzone having a third predetermined rate of change.
 4. A light controlsystem for controlling the brightness of a plurality of electricalloads, comprising: a light sensor that outputs a first signal inresponse to being exposed to a radiation source; a detection circuitcoupled to the light sensor, the detection circuit configured togenerate a second signal from the first signal; a control device coupledto receive the second signal from the detection circuit to control theplurality of electrical loads; a first zone of the plurality ofelectrical loads, having a first predetermined rate of change, the firstzone coupled to the control device to control the brightness of theplurality of electrical loads in the first zone at the firstpredetermined rate of change responsive to the radiation detected; asecond zone of the plurality of electrical loads, having a secondpredetermined rate of change, the second zone coupled to the controldevice to control the brightness of the plurality of electrical loads inthe second zone at the second predetermined rate of change responsive tothe radiation detected; and a third zone of the plurality of electricalloads, having a third predetermined rate of change, the third zonecoupled to the control device to control the brightness of the pluralityof electrical loads in the third zone at the third predetermined rate ofchange responsive to the radiation detected.
 5. A method for adjusting aplurality of electrical loads in a plurality of zones, comprising thesteps of: determining the ambient light level proximately near theplurality of electrical loads; generating a control signal to enable theplurality of electrical loads to be turned on; and adjusting apredetermined rate of change for each zone having the plurality ofelectrical loads responsive to the control signal.
 6. A method asrecited in claim 5, wherein the plurality of zones includes a firstzone, a second zone and a third zone, wherein the first zone having afirst pre-determine rate of change, the second zone having a secondpredetermined rate of change, and a third zone having a thirdpredetermined rate of change.